A smart box system may include a smart box device. The smart box device may include a top portion, elongated side portions, and side portions. The top portion may include a top set of locking elements configured to mate with an external device to prevent the external device from moving relative the top portion of the smart box device. The elongated side portions may attach to the top portion. The side portions may selectively attach to distal ends of the elongated side portions.

An exercise form analysis and feedback system (EFAF) including at least one sensor, at least one local movement data receiver, an analysis and feedback processing unit (AFPU) and a feedback display. The EFAF system of the present invention obtains lift movement data through the one or more sensors as lift movements are performed. This lift movement data may, in turn, be transmitted to one or more local movement data receivers such that the AFPU may operate on the lift movement data to provide real-time or near real-time form/technique feedback to the user via a feedback display. The system of the presentation invention uses machine learning techniques to provide feedback on lift quality aspects based on data associated with previous lifts and external data as applicable.

An exercise system including a tower and a translatable and rotatable display is disclosed. The tower is a free-standing unit and includes a mast that supports the display at a sufficient height or elevation, for example above a front panel of the system's housing. A carriage assembly couples the display to the mast to enable translation of the display between two positions, and the display mount is further configured to enable rotation of the display between a portrait orientation and an landscape orientation when the display is in the second position. In some embodiments, rotation of the display is substantially inhibited by the system's housing, for example the front panel, when the display is in the first position.

The various embodiments of the present invention provide a system and method for a fully mobile, non-invasive, continuous system for monitoring the cardiovascular and musculoskeletal health of an individual during exercise, and for administering a protocol for ischemic pre-conditioning. The system includes a wearable devices affixed on the user with a chest strap, coupled with an application running on a computing device (smartphone/smartwatch), which performs various computations on the wearable device, and allows the user to get real time alerts during exercise, by way of vibrations or audio messages or notifications on the gateway device, to guide them through a protocol for ischemic pre-conditioning.

A let detection system includes a sensor including an accelerometer attached to a tennis net. The sensor is in wireless communication with an umpire device able to send a message to the sensor, wherein the message causes the sensor to calibrate and begin monitoring for a let. The sensor determines a three-dimensional (3D) vector representing the gravity acting on the sensor as a baseline. When the sensor detects vertical acceleration of the net relative to the baseline and the vertical motion is above a preset threshold, the sensor automatically transmits a let notification message to the umpire device.

A speed generation method for simulating riding is provided. A computer device (20) retrieves a riding weight and road condition information, selects one of a plurality of preset gear ratios (30) as a selected gear ratio, retrieves a wheel rotating speed of a bicycle (4), and determines a simulated speed in a simulating riding service based on the selected gear ratio, a tire parameter, and the rotating speed.

An electronic device may receive log information regarding a motion of a wearable device from the wearable device, determine a value of at least one of one or more mobile parameters to be applied to a robot parameter algorithm for calculating a value of a robot parameter used to control the wearable device based on the log information, and determine the value of the robot parameter based on the robot parameter algorithm and the determined value of at least one of the mobile parameters.

In a first aspect, a method for monitoring a golf swing is provided that includes coupling a mobile telephone to a golf club and employing the mobile telephone coupled to the golf club to monitor acceleration of the mobile telephone as the mobile telephone swings while a user swings the golf club, collect acceleration information based on the monitored acceleration of the mobile telephone as the mobile telephone swings, analyze the collected acceleration information to determine one or more characteristics of the golf swing based on the collected acceleration information, and output information regarding the one or more characteristics of the golf swing on the display of the mobile telephone. Numerous other aspects are provided.

A head guard is provided. The head guard includes one or more sensors as part of an sensory input and communications system. The head guard wirelessly communicates data to remote computing devices for intelligent data collection.

Sleeves for improving performance and control are disclosed. The sleeves are constructed for use on the fingers, wherein each sleeve is constructed in some embodiments with grip zones that match areas of the finger to ensure improved grip while maintaining flexibility, compression, protection, and material durability. Each grip zone is positioned to ensure that fingers are able to naturally bend without impeding grip performance. A spine on a rear of the sleeve ensures material durability, limits over extension, and provides padding and protection.